CN113176428A - Current distortion eliminating system and method for working condition simulation of cascaded converter - Google Patents

Abstract

The invention provides a current distortion eliminating system and method for working condition simulation of a cascade converter, which comprises the following steps: the current generator is used for providing test current and direct-current power supply voltage and sending the test current and the direct-current power supply voltage to the current controller; meanwhile, receiving an internal switching device control signal generated by a current controller; the test module group is used for providing port voltage of the test bridge arm and sending the port voltage to the current controller; the voltage controller is used for providing modulation voltage of the test bridge arm and sending the modulation voltage to the current controller; the current controller generates an internal switching device control signal of the current generator according to the test current, the direct-current power supply voltage, the port voltage and the modulation voltage, outputs the internal switching device control signal to the current generator, compensates the bridge arm voltage of the step wave into a sine wave by dynamically compensating a voltage error introduced by the nearest level approximation control, thereby eliminating the distortion of the test current and improving the waveform of the test current. The invention can obviously improve the current control effect and improve the test precision.

Description

Current distortion eliminating system and method for working condition simulation of cascaded converter

Technical Field

The invention relates to the technical field of power electronics, in particular to a current distortion eliminating system and method for working condition simulation of a cascaded converter.

Background

In recent years, the cascaded converter is widely applied and paid attention to in medium-high voltage high-power fields due to the characteristics of modularization, easiness in expansion, low ripple waves and the like. However, as the voltage class and the capacity of the cascaded converter are continuously increased, the number of sub-modules of the cascaded converter becomes very large, and the reliability of the cascaded converter also depends on the reliability of the sub-modules. In order to ensure reliable operation of the cascaded converter system, verification and test of the submodules thereof become very important.

At present, the main modulation method of the cascade converter is the nearest level approximation modulation, but because a single or a small number of tested sub-modules are mostly arranged in a working condition simulation test circuit, the output voltage of a test bridge arm formed by a plurality of tested sub-modules in the actual test process presents a step waveform with a small number of levels, the frequent steps of the output voltage inevitably cause the drastic change of the outlet voltage of the current generator, and further act on a current controller, so that the serious distortion of the test current is caused. Therefore, it is urgently needed to provide an effective current distortion elimination method, which can eliminate the influence caused by the bridge arm voltage step, improve the test current waveform, and make the operation condition of the tested sub-module closer to the actual system.

At present, no explanation or report of the similar technology of the invention is found, and similar data at home and abroad are not collected.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides a current distortion eliminating system and method for working condition simulation of a cascade converter.

According to one aspect of the invention, a current distortion elimination system for simulating the working condition of a cascade type converter is provided, which comprises:

the current generator is used for providing test current and direct-current power supply voltage and sending the test current and the direct-current power supply voltage to the current controller; meanwhile, receiving an internal switching device control signal generated by a current controller;

the test module group is used for providing port voltage of a test bridge arm and sending the port voltage to the current controller;

the voltage controller is used for providing modulation voltage of the test bridge arm and sending the modulation voltage to the current controller;

and the current controller generates an internal switching device control signal of the current generator according to the test current, the direct-current power supply voltage, the port voltage and the modulation voltage and outputs the internal switching device control signal to the current generator.

Preferably, the current generator comprises at least one full bridge circuit, wherein two legs of each full bridge circuit respectively receive independent internal switching device control signals.

Preferably, the test module group includes two test bridge arms corresponding to different operating conditions, each of the test bridge arms includes a plurality of tested sub-modules connected in series, and the tested sub-modules in the same test bridge arm correspond to the same operating condition.

Preferably, the test bridge arms in the test module group can be randomly changed in combination mode without changing the electrical connection relationship, i.e. recombined or split; the arrangement mode of the submodules in the test bridge arm can be changed at will under the condition of not changing the electrical connection relation, and the change does not affect the basic characteristics of the test circuit.

Preferably, the current controller includes:

the feedforward controller receives the port voltage of the test bridge arm output by the test module group and the modulation voltage of the test bridge arm output by the voltage controller and generates compensation voltage;

the PIR controller receives the test current output by the current generator and the reference current input from the outside and generates a regulating voltage;

and the signal modulation module generates an internal switching device control signal of the current generator according to the direct-current power supply voltage output by the current generator, the compensation voltage output by the feedforward controller and the regulation voltage output by the PIR controller.

Preferably, the feedforward controller outputs the modulation voltage V of the test bridge arm output by the voltage controller_mod1(2)And the port voltage V of the test bridge arm output by the test module group_arm1(2)Making difference to obtain compensation voltage signal V_com1(2)：

V_com1(2)＝V_mod1(2)-V_arm1(2)。

Preferably, the test diePort voltage V of test bridge arm output by block group_arm1(2)Obtained by any one of the following modes:

in the first mode, the port voltage of a test bridge arm is measured in real time through a voltage sampling device;

in the second mode, the capacitance voltage V of the tested submodule of the test bridge arm is obtained_1(2).1-NAnd a control signal G_1(2).1-NThe calculation is carried out in the following way:

wherein the control signal G_1(2).1-NGenerated by the voltage controller.

Preferably, the PIR controller couples the reference current i_refAnd the test current i_tObtaining a test current difference value by differentiating, and obtaining an adjusting voltage v after the test current difference value is responded by PIR_bal：

Wherein, K_p、K_iAnd K_rThe coefficients are respectively the proportion, integral and resonance coefficient of current control, s is a complex parameter variable in Laplace transformation, and omega is resonance angular frequency.

Preferably, the signal modulation module adopts a pulse width modulation method according to the direct-current power supply voltage V_tThe compensation voltage V_arm1(2)And the regulating voltage v_balAnd jointly calculating to obtain a control signal V of an internal switching device of the current generator_o1(2)：

Control signal V_o1(2)Divided by the DC supply voltage V_tObtaining the control signal of per unit value, finally adjusting the pulse widthThe method obtains the actual control signal S of the internal switch device of the full bridge circuit in the current generator_1-4。

According to another aspect of the invention, a current distortion elimination method for simulating the working condition of a cascade type converter is provided, which comprises the following steps: by adopting the current distortion elimination system for the working condition simulation of the cascade type converter, the port voltage of the testing bridge arm of the step wave is compensated into the sine wave by dynamically compensating the voltage error introduced by the nearest level approximation control, so that the distortion of the testing current is eliminated, the waveform of the testing current is improved, and the testing current flowing through the tested sub-module is kept the same as that in the actual cascade type converter.

The invention provides a current distortion eliminating system and method for working condition simulation of a cascade converter, which is a test current control method for working condition simulation test of the cascade converter when a latest level approaches to modulation.

Due to the adoption of the technical scheme, compared with the prior art, the invention has the following beneficial effects:

the current distortion eliminating system and method for the working condition simulation of the cascaded converter solve the problem of current distortion when a test bridge arm presents low-level step wave characteristics, remove the limitation on the number of sub-modules to be tested and effectively improve the flexibility of the test.

The current distortion eliminating system and the method for the working condition simulation of the cascaded converter automatically generate the control signal of the current generator through the current control module, so that the test current waveform is consistent with the cascaded converter submodule in actual operation, the working condition simulation of the cascaded converter submodule under recent level approximation modulation is realized, and the test precision is obviously improved.

The current distortion eliminating system and method for working condition simulation of the cascade converter can obviously improve the test current waveform under various operating conditions through the realization of a digital signal processor, an arithmetic circuit or software, thereby meeting the requirement of flexibly applying different electric and thermal stresses to a tested submodule.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

fig. 1 is a schematic structural diagram of a current distortion elimination system and a working schematic diagram of a method for working condition simulation of a cascaded converter according to an embodiment of the present invention;

fig. 2 is a schematic waveform diagram of a test bridge arm modulation voltage and a port voltage in the system and method for eliminating current distortion for working condition simulation of a cascaded converter according to a preferred embodiment of the present invention;

fig. 3 is a schematic structural diagram of a first test bridge arm in a current distortion elimination system for working condition simulation of a cascaded converter according to a preferred embodiment of the present invention;

fig. 4 is a schematic structural diagram of a second test bridge arm in the current distortion elimination system for working condition simulation of the cascaded converter according to a preferred embodiment of the present invention.

In the figure: 1 is a current generator; 2 is a test module group; 3 is a voltage controller; 4 is a current controller; 41 is a feedforward controller; 42 is PIR controller; and 43 is a signal modulation module.

Detailed Description

The following examples illustrate the invention in detail: the embodiment is implemented on the premise of the technical scheme of the invention, and a detailed implementation mode and a specific operation process are given. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention.

Fig. 1 is a schematic structural diagram of a current distortion elimination system for simulating a working condition of a cascaded converter according to an embodiment of the present invention.

As shown in fig. 1, the current distortion elimination system for simulating the operating condition of the cascaded converter provided in this embodiment may include the following components:

the current generator is used for providing test current and direct-current power supply voltage and sending the test current and the direct-current power supply voltage to the current controller; meanwhile, receiving an internal switching device control signal generated by a current controller;

the test module group is used for providing port voltage of a test bridge arm and sending the port voltage to the current controller;

the voltage controller is used for providing modulation voltage of the test bridge arm and sending the modulation voltage to the current controller;

and the current controller generates an internal switching device control signal of the current generator according to the test current, the direct-current power supply voltage, the port voltage and the modulation voltage and outputs the internal switching device control signal to the current generator.

As a preferred embodiment of this embodiment, the current generator may comprise at least one full bridge circuit, wherein two legs of each full bridge circuit respectively receive independent internal switching device control signals.

As a preferred embodiment of this embodiment,

the test module group comprises two test bridge arms corresponding to different operation conditions, each test bridge arm comprises a plurality of tested sub-modules connected in series, and the tested sub-modules in the same test bridge arm correspond to the same operation condition. The test bridge arm structure is shown in fig. 3 and 4.

The test bridge arms in the test module group can be randomly changed in combination mode under the condition of not changing the electrical connection relation, namely, recombination or splitting is carried out; the arrangement mode of the submodules in the test bridge arm can be changed at will under the condition of not changing the electrical connection relation, and the change does not affect the basic characteristics of the test circuit.

As a preferred embodiment of this embodiment, the current controller may include:

the feedforward controller receives the port voltage of the test bridge arm output by the test module group and the modulation voltage of the test bridge arm output by the voltage controller and generates compensation voltage;

the PIR controller receives the test current output by the current generator and the reference current input from the outside and generates a regulating voltage;

and the signal modulation module generates an internal switching device control signal of the current generator according to the direct-current power supply voltage output by the current generator, the compensation voltage output by the feedforward controller and the regulation voltage output by the PIR controller.

As a preferred embodiment of the embodiment, the feedforward controller outputs the modulation voltage V of the test bridge arm output by the voltage controller_mod1(2)And the port voltage V of the test bridge arm output by the test module group_arm1(2)Making difference to obtain compensation voltage signal V_com1(2)：

V_com1(2)＝V_mod1(2)-V_arm1(2)。

Wherein, the subscripts 1 and 2 correspond to the first test bridge arm and the second test bridge arm respectively.

As a preferred embodiment of the embodiment, the port voltage V of the test bridge arm output by the test module group_arm1(2)Obtained by any one of the following modes:

in the first mode, the port voltage of a test bridge arm is measured in real time through a voltage sampling device;

in the second mode, the capacitance voltage V of the tested submodule of the test bridge arm is obtained_1(2).1-NAnd a control signal G_1(2).1-NThe calculation is carried out in the following way:

wherein the control signal G_1(2).1-NGenerated by a voltage controller.

As a preferred embodiment of this embodiment, the PIR controller will reference the powerStream i_refAnd a test current i_tObtaining a test current difference value by differentiating, and obtaining an adjusting voltage v after the test current difference value is responded by PIR_bal：

Wherein, K_p、K_iAnd K_rThe coefficients are respectively the proportion, integral and resonance coefficient of current control, s is a complex parameter variable in Laplace transformation, and omega is resonance angular frequency.

As a preferred embodiment of the embodiment, the signal modulation module adopts a pulse width modulation method according to the dc power voltage V_tCompensating voltage V_arm1(2)And regulating the voltage v_balThe control signal V of the internal switch device of the current generator is obtained by common calculation_o1(2)：

Control signal V_o1(2)Divided by the DC supply voltage V_tObtaining a per unit valued control signal, and finally obtaining an actual control signal S of a switch device in a full bridge circuit in the current generator by a pulse width modulation method_1-4。

Wherein, 1 and 2 in the subscript correspond to the first test bridge arm and the second test bridge arm respectively.

Another embodiment of the present invention provides a current distortion elimination method for working condition simulation of a cascaded converter, as shown in fig. 1, a current distortion elimination system for working condition simulation of a cascaded converter according to any one of the above embodiments of the present invention may be adopted, and a voltage error introduced by a nearest level approximation control is dynamically compensated, so as to compensate a port voltage of a test bridge arm of a step wave into a sine wave, thereby eliminating distortion of a test current, and improving a test current waveform, so that the test current flowing through a sub-module to be tested is kept the same as that in an actual cascaded converter.

The technical solutions provided by the above embodiments of the present invention are further described in detail below with reference to the accompanying drawings.

Fig. 1 is a schematic structural diagram of a current distortion eliminating system for working condition simulation of a cascaded converter in the above embodiment of the present invention and a working principle diagram of the method.

As shown in fig. 1, the current distortion eliminating system for simulating the operating condition of the cascaded converter in the above embodiment includes: the testing method comprises the following steps that (1) a current generator, a testing module group 2, a voltage controller 3 and a current controller 4 are carried out; wherein:

the method comprises the steps that a current generator 1 is adopted to provide test current and direct-current power supply voltage, the test current and the direct-current power supply voltage are sent to a current controller 4, and a control signal of a switching device generated by the current controller 4 is received;

the test module group 2 is adopted to provide the port voltage of the test bridge arm and send the port voltage to the current controller 4;

a voltage controller 3 is adopted to provide modulation voltage of a testing bridge arm, and the modulation voltage is sent to a current controller 4;

the current controller 4 is adopted to compensate the voltage error introduced by the nearest level approximation control through dynamic compensation, and the bridge arm voltage of the step wave is compensated into sine wave, so that the distortion of the test current is eliminated, and the waveform of the test current is improved.

A preferred embodiment of the present invention provides a current distortion elimination system for simulating the operating condition of a cascaded converter, which may include:

the current generator is used for sending the generated test current and the direct-current power supply voltage to the current controller;

the test module group comprises two test bridge arms formed by connecting a plurality of tested sub-modules in series, and the port voltage of the test bridge arms is sent to the current controller;

the voltage controller is used for generating a control signal of the tested submodule and sending the generated test bridge arm modulation voltage signal to the current controller;

the current controller dynamically compensates the difference value between the port voltage and the modulation voltage of the testing bridge arm through the feedforward controller so as to eliminate the testing current distortion caused by the testing bridge arm, further eliminates the influence of control errors and calculation precision through the proportional-integral resonance controller, and finally generates a control signal of a switching device inside the current generator through the signal modulation module so as to keep the testing current flowing through the tested submodule the same as that in the actual cascade converter.

In some embodiments of the present invention, as shown in fig. 1, the current controller 4 receives a test current signal and a dc power voltage signal generated by the current generator 1, receives a port voltage signal of a test bridge arm in the test module group 2, and a test bridge arm modulation voltage signal output by the voltage controller 3, and uses the port voltage signal and the test bridge arm modulation voltage signal as input signals for generating a switching device control signal in the current generator 1. The feedforward controller 41 is introduced into the current controller 4 to eliminate the test current distortion caused by the test bridge arm, meanwhile, the proportional-Integral-Resonance (PIR) controller 42 is used to further eliminate the influence of control error and calculation accuracy, and finally, the signal modulation module 43 generates a control signal of the internal switching device of the current generator, so that the test current flowing through the tested sub-module is kept the same as that in the actual cascaded converter.

The current controller 4 includes: a feedforward controller 41, a PIR controller 42 and a signal modulation module 43; wherein:

the inputs to the feedforward controller 41 include: testing the port voltage of the bridge arm in the module group 2; the test bridge arm modulation voltage signal output by the voltage controller 3;

inputs to the PIR controller 42 include: a test current signal generated by the current generator 1 and a reference current signal input through the outside;

the signal modulation module 43 generates control signals of each switching device in the current generator 1 together by using a pulse width modulation method according to the dc power voltage output by the current generator 1, the compensation voltage signal output by the feedforward controller 41, and the regulation voltage signal output by the PIR controller 42.

In some embodiments of the present invention, waveforms of the modulation voltage of the test bridge arm and the port voltage under typical conditions are schematically shown in fig. 2. The feedforward controller 41 modulates the voltage V by the test bridge arm output by the voltage controller 3_mod1(2)And test module group 2 middle testPort voltage V of test bridge arm_arm1(2)Differencing to obtain a compensated voltage signal V_com1(2)：

V_com1(2)＝V_mod1(2)-V_arm1(2)

Port voltage V of test bridge arm used in feedforward controller 41_arm1(2)Can be generated by:

in the first mode, the port voltage of the test bridge arm is directly obtained by real-time measurement through a voltage sampling device;

in the second mode, the port voltage of the test bridge arm passes through the capacitance voltage V of the tested submodule_1(2).1-NAnd a control signal G_1(2).1-NAnd calculating to obtain the expression:

the PIR controller 42 provides a reference current signal i_refWith the test current signal i generated by the current generator 1_tObtaining a test current difference value by carrying out subtraction, and obtaining an adjusting voltage signal v after the test current difference value passes through a PIR response link_balThe specific expression is as follows:

wherein, K_p、K_iAnd K_rThe proportional, integral and resonance coefficients of the current control are respectively, and omega is the resonance angular frequency.

In some embodiments of the present invention, the current generator 1 includes a dc power supply, a full bridge circuit, and an outlet inductor filter; the signal modulation module 43 generates control signals of the internal switching devices of the full-bridge circuit, and two bridge arms of the full-bridge circuit respectively receive independent control signals.

In the signal modulation module 43 according to the DC power voltage V outputted by the current generator 1_tThe compensation voltage signal V output by the feedforward controller 41_arm1(2)And a regulated voltage signal v output by the PIR controller 42_balAnd the control signals V of the two bridge arms of the full bridge circuit in the current generator 1 are obtained by common calculation_o1(2)The expression is as follows:

control signal V_o1(2)Divided by the DC supply voltage V_tObtaining a per unit valued control signal, and finally obtaining an actual control signal S of a switch device inside a full bridge circuit in the current generator 1 by a pulse width modulation method_1-4。

The test module group 2 includes two test bridge arms composed of a plurality of tested sub-modules, the tested sub-modules inside the test bridge arms are mainly composed of bridge converter topologies and capacitors thereof in any one structure, and fig. 3 and 4 are two structures that the test bridge arms can adopt respectively.

In the system and method for eliminating current distortion in working condition simulation of a cascaded converter provided in the embodiments of the present invention, in a working condition simulation test circuit of a cascaded converter submodule, the simulated cascaded converter submodule works in the cascaded converter system, and a tested submodule works in the working condition simulation test circuit, so as to make the electrical characteristics of the tested submodule the same as the electrical characteristics of a submodule working in the cascaded converter. The working condition simulation test circuit of the cascaded converter submodule provided by the embodiment works under the nearest level approximation modulation. The above calculation steps are realized by a chip including a digital signal processor and an FPGA, an arithmetic circuit or software.

The current distortion eliminating system and method for the working condition simulation of the cascaded converter, provided by the embodiment of the invention, solve the problem of current distortion when a test bridge arm presents low-level step wave characteristics, remove the limitation on the number of sub-modules to be tested and effectively improve the flexibility of the test; the control signal of the current generator is automatically generated through the current control module, so that the test current waveform is consistent with the cascaded converter submodule in actual operation, the working condition simulation of the cascaded converter submodule under the nearest level approximation modulation is realized, and the test precision is obviously improved; the testing current waveform can be obviously improved under various operating conditions through the realization of a digital signal processor, an arithmetic circuit or software, thereby meeting the requirements of flexibly applying different electric and thermal stresses to the tested submodule.

The foregoing description of specific embodiments of the present invention has been presented. It is to be understood that the present invention is not limited to the specific embodiments described above, and that various changes and modifications may be made by one skilled in the art within the scope of the appended claims without departing from the spirit of the invention.

Claims (10)

1. A current distortion elimination system for simulating the working condition of a cascade type converter is characterized by comprising:

the current generator is used for providing test current and direct-current power supply voltage and sending the test current and the direct-current power supply voltage to the current controller; meanwhile, receiving an internal switching device control signal generated by a current controller;

the test module group is used for providing port voltage of a test bridge arm and sending the port voltage to the current controller;

the voltage controller is used for providing modulation voltage of the test bridge arm and sending the modulation voltage to the current controller;

and the current controller generates an internal switching device control signal of the current generator according to the test current, the direct-current power supply voltage, the port voltage and the modulation voltage and outputs the internal switching device control signal to the current generator.

2. The system of claim 1, wherein the current generator comprises at least one full bridge circuit, and two arms of each full bridge circuit respectively receive independent internal switching device control signals.

3. The system for eliminating current distortion of working condition simulation of a cascaded converter according to claim 1, wherein the test module set comprises two test bridge arms corresponding to different operating conditions, each test bridge arm comprises a plurality of tested sub-modules connected in series, and the tested sub-modules in the same test bridge arm correspond to the same operating condition.

4. The system for eliminating current distortion of working condition simulation of the cascaded converter according to claim 3, wherein the test bridge arms in the test module group can be recombined or split in any form without changing the electrical connection relationship; the tested submodules in the testing bridge arm can be arranged in any form under the condition of not changing the electrical connection relation.

5. The system of claim 1, wherein the current controller comprises:

the feedforward controller receives the port voltage of the test bridge arm output by the test module group and the modulation voltage of the test bridge arm output by the voltage controller and generates compensation voltage;

the PIR controller receives the test current output by the current generator and the reference current input from the outside and generates a regulating voltage;

and the signal modulation module generates an internal switching device control signal of the current generator according to the direct-current power supply voltage output by the current generator, the compensation voltage output by the feedforward controller and the regulation voltage output by the PIR controller.

6. The system for eliminating current distortion of working condition simulation of the cascaded converter according to claim 5, wherein the feedforward controller outputs the modulation voltage V of the test bridge arm output by the voltage controller_mod1(2)And the port voltage V of the test bridge arm output by the test module group_arm1(2)Making difference to obtain compensation voltage signal V_com1(2)：

V_com1(2)＝V_mod1(2)-V_arm1(2)。

7. The system for eliminating current distortion of working condition simulation of cascaded current transformer as claimed in claim 6, wherein port voltage V of test bridge arm output by said test module group_arm1(2)Obtained by any one of the following modes:

in the first mode, the port voltage of a test bridge arm is measured in real time through a voltage sampling device;

in the second mode, the capacitance voltage V of the tested submodule of the test bridge arm is obtained_1(2).1-NAnd a control signal G_1(2).1-NThe calculation is carried out in the following way:

wherein the control signal G_1(2).1-NGenerated by the voltage controller.

8. The system of claim 5, wherein the PIR controller is configured to apply the reference current i to the current distortion cancellation system for operating condition simulation of the cascaded converter_refAnd the test current i_tObtaining a test current difference value by differentiating, and obtaining an adjusting voltage v after the test current difference value is responded by PIR_bal：

Wherein, K_p、K_iAnd K_rThe coefficients are respectively the proportion, integral and resonance coefficient of current control, s is a complex parameter variable in Laplace transformation, and omega is resonance angular frequency.

9. The system as claimed in claim 5, wherein the signal modulation module employs pulse width modulationModulation method according to the DC power supply voltage V_tThe compensation voltage V_arm1(2)And the regulating voltage v_balAnd jointly calculating to obtain a control signal V of an internal switching device of the current generator_o1(2)：

Control signal V_o1(2)Divided by the DC supply voltage V_tObtaining a per unit valued control signal, and finally obtaining an actual control signal S of a switch device in a full bridge circuit in the current generator by a pulse width modulation method_1-4。

10. A method for eliminating current distortion of working condition simulation of a cascade converter is characterized by comprising the following steps: the current distortion elimination system for working condition simulation of the cascade converter according to any one of claims 1 to 9 is adopted, voltage errors introduced by nearest level approximation control are dynamically compensated, port voltages of a test bridge arm of a step wave are compensated into sine waves, so that distortion of test currents is eliminated, and test current waveforms are improved, so that the test currents flowing through a tested submodule are kept the same as those in an actual cascade converter.

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